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Review of lattice design for low emittance ring

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1 Review of lattice design for low emittance ring
R. Bartolini Diamond Light Source Ltd and John Adams Institute, Dept. of Physics, University of Oxford Low Emittance Rings Workshop, Crete 3rd October 2011

2 Low Emittance Rings Workshop,
Motivations Luminosity and brilliance scale together both increase with smaller emittances both increase with higher current (…within limits beam-beam, collective effects, diffraction, etc) and damping rings are required to generate small emittance beams for colliders Low Emittance Rings Workshop, Crete 3rd October 2011

3 Low Emittance Rings Workshop,
Motivations Light sources diffraction limited operation at 0.1nm requires 10’s pm Colliders (B-factories) 1036 cm-2 s-1 requires 2nm (5nm for superKEKB) as present state-of-the-art light sources Damping rings 500 pm H and 2 pm V (specs for ILC-DR) <100 pm H and 5 pm V (specs for CLIC-DR) Low Emittance Rings Workshop, Crete 3rd October 2011

4 Accelerator physics and technology challenges
This workshop’s programme ! Low emittance lattice solutions dynamic aperture and momentum aperture low emittance tuning Collective effects IBS e-cloud fast-ion, RW, CSR and others Advanced technology Damping wigglers - In-vacuum IDs high resolution BPMs optical diagnostics (laser wire, pinholes, etc) high vacuum (NEG coating and low SEY material) Injection schemes (time structure for DR and DA for light sources) this talk see R. Nagaoka’s talk see E. Wallen’s talk Low Emittance Rings Workshop, Crete 3rd October 2011

5 Emittance in 3rd GLS, DR and colliders
Low Emittance Rings Workshop, Crete 3rd October 2011

6 Low Emittance Rings Workshop,
Design challenges Low emittance lattices for light sources Low emittance lattices for damping rings motivations design approaches tools predicted performance Low Emittance Rings Workshop, Crete 3rd October 2011

7 3rd generation storage ring light sources
1992 ESRF, France (EU) 6 GeV ALS, US GeV 1993 TLS, Taiwan 1.5 GeV 1994 ELETTRA, Italy 2.4 GeV PLS, Korea 2 GeV MAX II, Sweden 1.5 GeV 1996 APS, US 7 GeV LNLS, Brazil GeV 1997 Spring-8, Japan 8 GeV 1998 BESSY II, Germany 1.9 GeV 2000 ANKA, Germany 2.5 GeV SLS, Switzerland 2.4 GeV 2004 SPEAR3, US 3 GeV CLS, Canada 2.9 GeV 2006: SOLEIL, France 2.8 GeV DIAMOND, UK 3 GeV ASP, Australia 3 GeV MAX III, Sweden 700 MeV Indus-II, India 2.5 GeV 2008 SSRF, China GeV 2009 PETRA-III, Germany 6 GeV 2011 ALBA, Spain 3 GeV ESRF Diamond

8 3rd generation storage ring light sources
under construction or planned NLSL-II > 2011 NSLS-II, US 3 GeV MAX-IV, Sweden GeV SOLARIS, Poland 3 GeV SESAME, Jordan 2.5 GeV TPS, Taiwan 3 GeV CANDLE, Armenia 3 GeV PEP-X, USA 4.5 GeV Spring8-II, Japan 6 GeV Max-IV Low Emittance Rings Workshop, Crete 3rd October 2011

9 3rd generation storage ring light sources
Low Emittance Rings Workshop, Crete 3rd October 2011

10 and Acc. Phys. and technology challenges
Users’ requirements and Acc. Phys. and technology challenges Photon energy Flux Brilliance Stability Polarisation Time structure Ring energy Small Emittance Insertion Devices High Current; Feedbacks Vibrations; Orbit Feedbacks; Top-Up Short bunches; Short pulses Low Emittance Rings Workshop, Crete 3rd October 2011

11 Brilliance with IDs (medium energy light sources)
Medium energy storage rings with in-vacuum undulators operated at low gaps (e.g. 5-7 mm) can reach 10 keV with a brilliance of 1020 ph/s/0.1%BW/mm2/mrad2 Low Emittance Rings Workshop, Crete 3rd October 2011

12 Brilliance with IDs (ESRF upgrade)
Brilliance gain on the ESRF upgrade driven by higher stored current and smaller vertical emittance Low Emittance Rings Workshop, Crete 3rd October 2011

13 Low emittance lattices
Lattice design has to provide low emittance and adequate space in many straight sections to accommodate long Insertion Devices Minimise  and D and be close to a waist in the dipole Zero dispersion in the straight section was used especially in early machines avoid increasing the beam size due to energy spread hide energy fluctuation to the users allow straight section with zero dispersion to place RF and injection decouple chromatic and harmonic sextupoles DBA and TBA lattices provide low emittance with large ratio between Flexibility for optic control for apertures (injection and lifetime)

14 3rd generation storage ring LS and damping rings
Lattice Design: DBA, TBA, Multi-Bend Lattice, TME-Structure controlled dispersion in straight sections Radiation Excitation and Damping Manipulations: Damping Wiggler : PETRA-III, NSLS-II, MAX IV, PEP-X, Damping Rings Combined B (Partition Control) Robinson Wiggler (Partition Control) see L. Nadolski’s talk Longitudinally Variable B (Optimized Radiation Integral) see C. Wang’s talk Low Emittance Rings Workshop, Crete 3rd October 2011

15 Double Bend Achromat (DBA) Triple Bend Achromat (TBA)
DBA and TBA Double Bend Achromat (DBA) Triple Bend Achromat (TBA) APS DBA used at: ESRF, ELETTRA, APS, SPring8, Bessy-II, Diamond, SOLEIL, SPEAR3 ... TBA used at ALS, SLS, PLS, TLS ALS

16 Breaking the achromatic condition
Leaking dispersion in straight sections reduces the emittance ESRF 7 nm  3.8 nm APS 7.5 nm  2.5 nm SPring8 4.8 nm  3.0 nm SPEAR nm  9.8 nm ALS (SB) 10.5 nm  6.7 nm APS The emittance is reduced but the dispersion in the straight section increases the beam size ASP Need to make sure the effective emittance and ID effects are not made worse

17 Low emittance lattices
MAX-IV New designs envisaged to achieve sub-nm emittance involve Damping Wigglers Petra-III: 1 nm NSLS-II: 0.5 nm MBA MAX-IV (7-BA): 0.5 nm Spring-8 (10-BA): 83 pm (2006) 10-BA had a DA –6.5 mm +9 mm reverted to a QBA (160 pm) now 6BA with 70 pm see K. Soutome’s talk Spring-8 upgrade

18 Max-IV 20-fold 7-BA achromat
Max-IV studies proved that a 7-BA (330 pm, and 260 pm with DW) can deliver suffcient DA and MA to operate with standard injection schemes Tools used FM – driving terms Additional octupoles were found to be effective Courtesy S. Leemans

19 PEP-X 7 bend achromat cell
Natural emittance = 29 pm-rad at 4.5 GeV 5 TME units Cell phase advances: mx=(2+1/8) x 3600, my=(1+1/8) x 3600. Courtesy B. Hettel Low Emittance Rings Workshop, Crete 3rd October 2011

20 Reduced emittance with damping wigglers
Emittance = 11 pm-rad at 4.5 GeV with parameters lw=5 cm, Bw=1.5 T Wiggler Field Optimization Wiggler Length Optimization Average beta function at the wiggler section is 12.4 meter. Courtesy Min-Huey Wang, B. Hettel, Y. Cai Low Emittance Rings Workshop, Crete 3rd October 2011

21 Cancellation of resonances
All Geometrical 3rd and 4th Resonances Driven by Strong Sextupoles except 2nx-2ny Third Order Fourth Order Courtesy Min-Huey Wang, B. Hettel, Y. Cai Low Emittance Rings Workshop, Crete 3rd October 2011

22 Additional sextupoles for tuneshift and 2nx-2ny
Without Harmonic Sextupoles With Harmonic Sextupoles Optimized with OPA (Accelerator Design Program from SLS PSI). Courtesy Min-Huey Wang, B. Hettel, Y. Cai Low Emittance Rings Workshop, Crete 3rd October 2011

23 Optimisation with parallel computing and ELEGANT
Dynamic Aperture at Injection Excellent design of an ultimate storage ring for PEP-X Approaching diffraction limit at one angstrom Reasonable beam current 200 mA Good beam lifetime 3 hours Good injection with 10 mm acceptance Achievable machine tolerances Low Emittance Rings Workshop, Crete 3rd October 2011 Courtesy Min-Huey Wang, B. Hettel, Y. Cai

24 New ILC Damping Ring Baseline Lattice
Usually damping rings lattices have a racetrack layout with long straight sections including RF cavities, injection, extraction and long wiggler sections Courtesy S. Guiducci Low Emittance Rings Workshop, Crete 3rd October 2011

25 DR for linear collider lattices
DR lattices are wiggler dominated: Wigglers are needed to achieve the required damping time Emittance with wigglers U0 = Uarc + Uwig = Uarc (1 + Fw) ex = ea/(1+Fw) + ew Fw/(1+Fw) For linear collider damping rings: ew << ea ; Fw>>1 ex ~ ea/Fw Courtesy S. Guiducci Low Emittance Rings Workshop, Crete 3rd October 2011

26 3.2 km Damping Ring - Lattice Comparison
DTC01, TME-style DSB3, SuperB-style DMC3, FODO All the arc cell styles satisfy emittance and damping time requirements. S. Guiducci, M. E. Biagini, “A Low Emittance Lattice for The ILC 3 Km Damping Ring”, IPAC’10 D. Wang, J. Gao, Y. Wang, “A New Design for ILC 3.2 km Damping Ring Based on FODO Cell”, IPAC’10 D. Rubin, DR TBR, LNF July 2011, S. Guiducci et al., , “Updates to the International Linear Collider Damping Rings Baseline Design”, IPAC’11

27 3.2 km ILC damping ring main parameters comparison
DSB3 DMC3 DTC01 Arc lattice SuberB-style FODO TME-style Energy (GeV) 5 Circumference (m) 3238 3220 3239 Horizontal Emittance (nm) 0.66 0.36 0.45 Damping time tx, ty (ms) 24 23 Energy spread % 0.12 0.13 0.11 Energy loss/turn U0 4.5 4.7 Fw = U0wiggler/U0arc 3.5 10.8 4.6 Wiggler field (T) 1.6 1.5 Total wiggler length (m) 78 95 104 Courtesy S. Guiducci Low Emittance Rings Workshop, Crete 3rd October 2011

28 ILC-CLIC Damping Ring comparisons
ILC-DCO4 ILC-DTC01 CLIC Arc lattice Modified FODO TME-style Modified TME Energy 5 2.86 Circumference (m) 6476 3239 493 Horizontal Emittance (nm) 0.45 0.079 Damping time tx (ms) 21 24 2.4 Energy spread 0.13 0.11 0.1 Energy loss/turn U0 (MeV) 10.2 4.5 3.9 Fw = Uarc/Uwiggler 10.7 4.6 6.9 Wiggler field (T) 1.6 1.5 2.5 Total wiggler length (m) 216 104 152 M.Korostelev, A.Wolski, “DCO4 Lattice Design For 6.4 Km ILC Damping Rings”, IPAC’10 Y. Papaphilippou et al., , “Lattice Options for the CLIC Damping Rings”, IPAC’09 Courtesy S. Guiducci

29 ILC Damping Ring Dynamic Aperture
DTC01 For ILC damping ring the DA has to be 3sx of the “large” positron beam, which is 130sx of the stored beam Courtesy S. Guiducci Low Emittance Rings Workshop, Crete 3rd October 2011

30 Non-linear optics optimisation and control with low emittance lattices
Low emittance  Large Nat. Chromaticity with Strong quads and Small Dispersion  Strong SX  Small Apertures (Dynamic and Momentum apertures) Usually the phase advance per cell is such that low resonance driving terms are automatically compensated (to first order) Numerical optimisation is however unavoidable need 6D tracking (watch out alpha_2) use DA and FM plots use MOGA ! MOGA in elegant to optimise 8 sextupole families at Diamond improved the Touschek lifetime by 20 % Low Emittance Rings Workshop, Crete 3rd October 2011

31 MOGA DA studies for NSLS-II
NLSL-II lattice  = 0.55 nm with damping wigglers with 3 damping wigglers Tracked DA directly used as objective as area of ellipses for different dp/p and-or detuning with amplitude Low Emittance Rings Workshop, Crete 3rd October 2011

32 Operational challenges
Implementation of the linear optics of low emittance lattices beta beating linear coupling Low emittance tuning Implementation of the non-linear optics Frequency Map Analysis Driving terms Low Emittance Rings Workshop, Crete 3rd October 2011

33 Light sources optics controls
Oxford 15 miles Diamond is a third generation light source open for users since January 2007 2.7 nm emittance – 18 beamlines in operation (10 in-vacuum small gap IDs) Most state-of-the-art light sources share the same structure

34 Diamond storage ring main parameters non-zero dispersion lattice
Energy 3 GeV Circumference m No. cells 24 Symmetry 6 Straight sections 6 x 8m, 18 x 5m Insertion devices 4 x 8m, 18 x 5m Beam current 300 mA (500 mA) Emittance (h, v) 2.7, 0.03 nm rad Lifetime > 10 h Min. ID gap 7 mm (5 mm) Beam size (h, v) 123, 6.4 mm Beam divergence (h, v) 24, 4.2 mrad (at centre of 5 m ID) Beam size (h, v) 178, 12.6 mm Beam divergence (h, v) 16, 2.2 mrad (at centre of 8 m ID) 48 Dipoles; 240 Quadrupoles; 168 Sextupoles (+ H and V orbit correctors + 96 Skew Quadrupoles) 3 SC RF cavities; 168 BPMs Quads + Sexts have independent power supplies

35 Linear optics modelling with LOCO Linear Optics from Closed Orbit response matrix – J. Safranek et al. Hor.  - beating Ver.  - beating Quadrupole gradient variation Modified version of LOCO with constraints on gradient variations (see ICFA Newsl, Dec’07)  - beating reduced to 0.4% rms Quadrupole variation reduced to 2% Results compatible with mag. meas. and calibrations LOCO allowed remarkable progress with the correct implementation of the linear optics

36 Measured emittances Coupling without skew quadrupoles off K = 0.9%
(at the pinhole location; numerical simulation gave an average emittance coupling 1.5% ± 1.0 %) Emittance [ ] (2.75) nm Energy spread [1.1e e3] (1.0e-3) After coupling correction with LOCO (2*3 iterations) 1st correction K = 0.15% 2nd correction K = 0.08% V beam size at source point 6 μm Emittance coupling 0.08% → V emittance 2.2 pm Variation of less than 20% over different measurements

37 Comparison machine/model and Lowest vertical emittance
Model emittance Measured emittance -beating (rms) Coupling* (y/ x) Vertical emittance ALS 6.7 nm 0.5 % 0.1% 4-7 pm APS 2.5 nm 1 % 0.8% 20 pm ASP 10 nm 0.01% 1-2 pm CLS 18 nm 17-19 nm 4.2% 0.2% 36 pm Diamond 2.74 nm nm 0.4 % 0.08% 2.0 pm ESRF 4 nm 1% 3.7 pm SLS 5.6 nm 5.4-7 nm 4.5% H; 1.3% V 0.04% SOLEIL 3.73 nm nm 0.3 % 4 pm SPEAR3 9.8 nm < 1% 0.05% 5 pm SPring8 3.4 nm nm 1.9% H; 1.5% V 6.4 pm SSRF 3.9 nm nm <1% 0.13% * best achieved

38 Low emittance tuning at Diamond and SLS for SuperB
Last year results on low emittance tuning and the achievement of a vertical emittance of 2.0 pm at Diamond and SLS have sparked quite some interest from the Damping ring community (CLIC and ILC) and from the Super B In collaboration with the SuperB team (P. Raimondi,. M. Biagini, S: Liuzzo) Diamond and SLS have been used as a test-bed for new techniques for low emittance tuning based on dispersion free steering and coupling free steering. 4 MD shifts at DLS November February 11 See S. Liuzzo’s talk

39 Low Emittance Rings Workshop,
State-of-the-art light sources have BPMs with turn-by-turn capabilities e.g. Diamond excite the beam diagonally measure tbt data at all BPMs colour plots of the FFT H BPM number QX = 0.22 H tune in H Qy = 0.36 V tune in V V All the other important lines are linear combination of the tunes Qx and Qy BPM number m Qx + n Qy frequency / revolution frequency Low Emittance Rings Workshop, Crete 3rd October 2011

40 ESRF coupling correction with spectral lines (I)
See A. Franchi’s talk Low Emittance Rings Workshop, Crete 3rd October 2011 Courtesy A. Franchi

41 ESRF coupling correction with spectral lines (II)
ESRF record low emittance June 2010 – At ID gaps open 4.4  0.7 pm Reduced to 3.7 pm with additioanl skew quadrupoles Compensation of coupling during ID gaps movement feedforward tables: gaps to skew quads via coupling measurements feedback: V emittance – skew quads via C- driving terms Courtesy A. Franchi Low Emittance Rings Workshop, Crete 3rd October 2011

42 Spectral line (-1, 1) in V associated with the sextupole resonance (-1,2)
Comparison spectral line (-1,1) from tracking data and measured (-1,1) observed at all BPMs Spectral line (-1,1) from tracking data observed at all BPMs model model; measured BPM number BPM number Low Emittance Rings Workshop, Crete 3rd October 2011

43 Frequency Analysis of Betatron Motion and Lattice Model Reconstruction
Using the measured amplitudes and phases of the spectral lines of the betatron motion we can build a fit procedure to calibrate the nonlinear model of the ring Accelerator Model Accelerator tracking data at all BPMs spectral lines from model (NAFF) beam data at all BPMs spectral lines from BPMs signals (NAFF) e.g. targeting more than one line Define the distance between the two vector of Fourier coefficients Least Square Fit of the sextupole gradients to minimise the distance χ2 of the two Fourier coefficients vectors

44 Simultaneous fit of (-2,0) in H and (1,-1) in V
(-1,1) (-2,0) sextupoles start iteration 1 iteration 2 FLS2010, SLAC, 02 March 2010 Both resonance driving terms are decreasing

45 Both resonances are controlled
Sextupole variation Now the sextupole variation is limited to < 5% Both resonances are controlled We measured a slight improvement in the lifetime (10%) Low Emittance Rings Workshop, Crete 3rd October 2011

46 SOLEIL’s – off momentum FM
Simulations Measurements Agreement few % up to dp/p 4 % Courtesy L. Nadolski Low Emittance Rings Workshop, Crete 3rd October 2011

47 Frequency map and detuning with momentum
comparison machine vs model (I) Using the measured Frequency Map and the measured detuning with momentum we can build a fit procedure to calibrate the nonlinear model of the ring Accelerator Model Accelerator tracking data build FM and detuning with momentum BPMs data with licked beams measure FM and detuning with momentum Gives a measure of the discrepancy between machine and model, i.e. ultimately how poorely we understand the resonances excited in the machine The distance between the two vectors can be used for a Least Square Fit of the sextupole gradients to minimise the distance χ2 of the two vectors

48 Frequency map and detuning with momentum
comparison machine vs model (II) detuning with momentum model and measured FM measured FM model Sextupole strengths variation less than 3% The most complete description of the nonlinear model is mandatory ! Measured multipolar errors to dipoles, quadrupoles and sextupoles (up to b10/a9) Correct magnetic lengths of magnetic elements Fringe fields to dipoles and quadrupoles Substantial progress after correcting the frequency response of the Libera BPMs FM and detuning used as a fit DA is a result

49 Frequency map and detuning with momentum
comparison machine vs model (III) Synchrotron tune vs RF frequency DA measured DA model The fit procedure based on the reconstruction of the measured FM and detuning with momentum describes well the dynamic aperture, the resonances excited and the dependence of the synchrotron tune vs RF frequency FM and detuning used as a fit; borders limited by the knowledge of the enginnering apertures DA is a result R. Bartolini et al. Phys. Rev. ST Accel. Beams 14, Low Emittance Rings Workshop, Crete 3rd October 2011

50 Comparison real lattice to model linear and nonlinear optics
Frequency Maps and amplitudes and phases of the spectral line of the betatron motion can be used to compare and correct the real accelerator with the model LOCO Closed Orbit Response Matrix from model fitting quadrupoles, etc Linear lattice correction/calibration Closed Orbit Response Matrix measured R. Bartolini and F. Schmidt in PAC05 Spectral lines + FMA from model fitting sextupoles and higher order multipoles Nonlinear lattice correction/calibration Spectral Lines + FMA measured FLS2010, SLAC, 02 March 2010 Combining the complementary information from FM and spectral line should allow the calibration of the nonlinear model and a full control of the nonlinear resonances

51 Conclusions Damping rings (CLIC – ILC), third generation light sources and recently proposed B-factories have many similarities and they all push their design to ultra low emittance These three worlds can profit from each others’ work Modeliing has reached impressive precision in the linear optics and significant progress has been made in the modelisation and correction of the nonlinear optics Standard tools like FMA and driving terms analysis, possibly complemented with MOGA-type apporaches seem adequate to generate sufficient DA and MA with MBA Emittance should be stable also wrt to orbit pertubations and collective effects Low Emittance Rings Workshop, Crete 3rd October 2011


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